Chapter 11 Managing Uncertainty in the Supply Chain: Safety Inventory

Chapter 11Managing Uncertainty in theSupply Chain: Safety Inventory

Outline • The role of safety inventory in a supply chain • Determining the appropriate level of safety inventory • Impact of supply uncertainty on safety inventory • Impact of aggregation on safety inventory • Impact of replenishment policies on safety inventory • Managing safety inventory in a multi-echelon supply chain • Estimating and managing safety inventory in practice

The Role of Safety Inventory in a Supply Chain • Forecasts are rarely completely accurate • If average demand is 1000 units per week, then half the time actual demand will be greater than 1000, and half the time actual demand will be less than 1000; what happens when actual demand is greater than 1000? • If you kept only enough inventory in stock to satisfy average demand, half the time you would run out • Safety inventory: Inventory carried for the purpose of satisfying demand that exceeds the amount forecasted in a given period

Role of Safety Inventory • Average inventory is therefore cycle inventory plus safety inventory • There is a fundamental tradeoff: • Raising the level of safety inventory provides higher levels of • product availability • customer service • Raising the level of safety inventory also raises the level of average inventory and therefore • holding costs

Two Questions to Answer in Planning Safety Inventory • What is the appropriate level of safety inventory to carry? • What actions can be taken to improve product availability while reducing safety inventory? Safety Stock SS

Reduce Inventory Reducing safety inventory L – lead time purchase mtrls transportationmaketransp.Customer sL- D – sd- Z

Determining the AppropriateLevel of Safety Inventory • Measuring demand uncertainty sd • Measuring product availability z • Replenishment policies • Impact of required product availability and uncertainty on safety inventory • Evaluating cycle service level and fill rate • Evaluating safety level given desired cycle service level or fill rate

Determining the AppropriateLevel of Demand Uncertainty • Appropriate level of safety inventory determined by: • supply or demand uncertainty Stdev. s • desired level of product availability Service Level (z) • s Higher levels of uncertainty require higher levels of safety inventory given a particular desired level of product availability • z Higher levels of desired product availability require higher levels of safety inventory given a particular level of uncertainty

Measuring Demand Uncertainty • Demand has a systematic component and a random component • The estimate of the random component is the measure of demand uncertainty • Random component is usually estimated by the standard deviation of demand • Notation: D = Average demand per period sD= standard deviation of demand per period L = lead time = time between when an order is placed and when it is received • Uncertainty of demand during lead time is what is important

Measuring Product Availability • Product availability: a firm’s ability to fill a customer’s order out of available inventory • Stockout: a customer order arrives when product is not available

Replenishment Policies • Replenishment policy: decisions regarding when to reorder and how much to reorder • Continuous review: inventory is continuously monitored and an order of size Q is placed when the inventory level reaches the reorder point ROP • Periodic review: inventory is checked at regular (periodic) intervals and an order is placed to raise the inventory to a specified threshold (the “order-up-to” level)

ROP: Reorder point L: Lead time for replenishment D: Average demand per unit time D:Standard deviation of demand per period DL:Mean demand during lead time L: Standard deviation of demand during lead time CSL: Cycle service level ss: Safety inventory Continuous Review Policy: Safety Inventory and Cycle Service Level Average Inventory = Q/2 + ss

Example 11.1: Estimating Safety Inventory (Continuous Review Policy) D = 2,500/week; D = 500 L = 2 weeks; Q = 10,000; ROP = 6,000 ss = -DL + ROP DL = DL = (2500)(2) = 5000 ss = ROP - RL = 6000 - 5000 = 1000 Cycle inventory = Q/2 = 10000/2 = 5000 Find: ss, service level ROP = DL + ss

Example 11.2: Estimating Cycle Service Level (Continuous Review Policy) D = 2,500/week; D = 500 L = 0 L = 2 weeks; Q = 10,000; ROP = 6,000 Cycle service level, CSL = F(DL + ss, DL, L) = = NORMDIST (DL + ss, DL, L) = NORMDIST(6000,5000,707,1) = 0.92 (This value can also be determined from a Normal probability distribution table) z=1.41

Example 11.4: EvaluatingSafety Inventory Given CSL D = 2,500/week; D = 500 L = 0 L = 2 weeks; Q = 10,000; CSL = 0.90 z=1.28 ROP=5906 DL = 5000, L = 707 (from earlier example) FIND: SaftyStock, Service Level ss = FS-1(CSL)L = [NORMSINV(0.90)](707) = 906 (this value can also be determined from a Normal probability distribution table)

Impact of Required Product Availability and Uncertainty on Safety Inventory • Demand uncertainty (sd) increases, required safety inventory increases • Managerial levers to reduce safety inventory without reducing product availability • reduce supplier lead time, L (better relationships with suppliers) • reduce uncertainty in demand, sd (better forecasts, better information collection and use)

Reduce Inventory Reducing safety inventory L – lead time purchase mtrls transportationmaketransp.Customer 5wks 2wk 2wk 2wk sL- why is transportation not consistent? D – sd- better forecast Z

Impact of Supply Uncertainty • D: Average demand per period • D: Standard deviation of demand per period • L: Average lead time • sL: Standard deviation of lead time

Impact of Supply Uncertainty D = 2,500/day; D = 500 L = 7 days; Q = 10,000; CSL = 0.90; z=1.28 sL = 7 days DL = DL = (2500)(7) = 17500 FIND: ROP ss = F-1s(CSL)sL = NORMSINV(0.90) x 17550 = 22,491

Impact of Supply Uncertainty Uncertainty in variations in Lead Time Safety inventory when sL = 0 is 1,695 Safety inventory when sL = 1 is 3,625 Safety inventory when sL = 2 is 6,628 Safety inventory when sL = 3 is 9,760 Safety inventory when sL = 4 is 12,927 Safety inventory when sL = 5 is 16,109 Safety inventory when sL = 6 is 19,298

Product Substitution • Substitution: use of one product to satisfy the demand for another product

Component Commonality • Using common components in a variety of different products • Can be an effective approach to exploit aggregation and reduce component inventories

Example 11.9: Value of Component Commonality Inventory Number of Products using the same component

Postponement • The ability of a supply chain to delay product differentiation or customization until closer to the time the product is sold • Goal is to have common components in the supply chain for most of the push phase and move product differentiation as close to the pull phase as possible • Examples: Dell, Benetton

Impact of ReplenishmentPolicies on Safety Inventory • Continuous review policies • Periodic review policies

Estimating and ManagingSafety Inventory in Practice • Account for the fact that supply chain demand is lumpy • Adjust inventory policies if demand is seasonal • Monitor service levels • Focus on reducing safety inventories

Summary of Learning Objectives • What is the role of safety inventory in a supply chain? • What are the factors that influence the required level of safety inventory? • What are the different measures of product availability? • What managerial levers are available to lower safety inventory and improve product availability?

Chapter 11 Managing Uncertainty in the Supply Chain: Safety Inventory